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1 CSC 222: Computer Programming II Spring 2005 Searching and efficiency  sequential search  big-Oh, rate-of-growth  binary search  example: spell checker.

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Presentation on theme: "1 CSC 222: Computer Programming II Spring 2005 Searching and efficiency  sequential search  big-Oh, rate-of-growth  binary search  example: spell checker."— Presentation transcript:

1 1 CSC 222: Computer Programming II Spring 2005 Searching and efficiency  sequential search  big-Oh, rate-of-growth  binary search  example: spell checker

2 2 Searching a list suppose you have a list, and want to find a particular item, e.g.,  lookup a word in a dictionary  find a number in the phone book  locate a student's exam from a pile searching is a common task in computing  searching a database  checking a login password  lookup the value assigned to a variable in memory if the items in the list are unordered (e.g., added at random)  desired item is equally likely to be at any point in the list  need to systematically search through the list, check each entry until found  sequential search

3 3 Sequential search sequential search traverses the list from beginning to end  check each entry in the list  if matches the desired entry, then FOUND (return its index)  if traverse entire list and no match, then NOT FOUND (return -1) recall: the ArrayList class has an indexOf method /** * Performs sequential search on the array field named items * @param desired item to be searched for * @returns index where desired first occurs, -1 if not found */ public int indexOf(Object desired) { for(int k=0; k < items.length; k++) { if (desired.equals(items[k])) { return k; } return -1; }

4 4 How efficient is sequential search? in the worst case:  the item you are looking for is in the last position of the list (or not found)  requires traversing and checking every item in the list  if 100 or 1,000 entries  NO BIG DEAL  if 10,000 or 100,000 entries  NOTICEABLE for this algorithm, the dominant factor in execution time is checking an item  the number of checks will determine efficiency in the average case? in the best case?

5 5 Big-Oh notation to represent an algorithm’s performance in relation to the size of the problem, computer scientists use Big-Oh notation an algorithm is O(N) if the number of operations required to solve a problem is proportional to the size of the problem sequential search on a list of N items requires roughly N checks (+ other constants)  O(N) for an O(N) algorithm, doubling the size of the problem requires double the amount of work (in the worst case)  if it takes 1 second to search a list of 1,000 items, then it takes 2 seconds to search a list of 2,000 items it takes 4 seconds to search a list of 4,000 items it takes 8 seconds to search a list of 8,000 items...

6 6 Searching an ordered list when the list is unordered, can't do any better than sequential search  but, if the list is ordered, a better alternative exists e.g., when looking up a word in the dictionary or name in the phone book  can take ordering knowledge into account  pick a spot – if too far in the list, then go backward; if not far enough, go forward binary search algorithm  check midpoint of the list  if desired item is found there, then DONE  if the item at midpoint comes after the desired item in the ordering scheme, then repeat the process on the left half  if the item at midpoint comes before the desired item in the ordering scheme, then repeat the process on the right half

7 7 Binary search /** * Performs binary search on a sorted list. * @param items sorted list of Comparable items * @param desired item to be searched for * @returns index where desired first occurs, -(insertion point)-1 if not found */ public static int binarySearch(List items, Comparable desired) { int left = 0;// initialize range where desired could be int right = items.length-1; while (left <= right) { int mid = (left+right)/2;// get midpoint value and compare int comparison = desired.compareTo(items[mid]); if (comparison == 0) {// if desired at midpoint, then DONE return mid; } else if (comparison < 0) {// if less than midpoint, focus on left half right = mid-1; } else {// otherwise, focus on right half left = mid + 1; } return /* CLASS EXERCISE */ ;// if reduce to empty range, NOT FOUND } the Collections utility class contains a binarySearch method  takes a List of Comparable items and the desired item ( List is an interface that specifies basic list operations, ArrayList implements List )  returns index of desired item if found, -(insertion_point) – 1 if not found

8 8 Visualizing binary search note: each check reduces the range in which the item can be found by half  see www.creighton.edu/~davereed/csc107/search.html for demowww.creighton.edu/~davereed/csc107/search.html

9 9 How efficient is binary search? in the worst case:  the item you are looking for is in the first or last position of the list (or not found) start with N items in list after 1 st check, reduced to N/2 items to search after 2 nd check, reduced to N/4 items to search after 3 rd check, reduced to N/8 items to search... after log 2 N checks, reduced to 1 item to search again, the dominant factor in execution time is checking an item  the number of checks will determine efficiency in the average case? in the best case?

10 10 Big-Oh notation an algorithm is O(log N) if the number of operations required to solve a problem is proportional to the logarithm of the size of the problem binary search on a list of N items requires roughly log 2 N checks (+ other constants)  O(log N) for an O(log N) algorithm, doubling the size of the problem adds only a constant amount of work  if it takes 1 second to search a list of 1,000 items, then searching a list of 2,000 items will take time to check midpoint + 1 second searching a list of 4,000 items will take time for 2 checks + 1 second searching a list of 8,000 items will take time for 3 checks + 1 second...

11 11 Comparison: searching a phone book Number of entries in phone book Number of checks performed by sequential search Number of checks performed by binary search 100 7 200 8 400 9 800 10 1,600 11 ……… 10,000 14 20,000 15 40,000 16 ……… 1,000,000 20 to search a phone book of the United States (~280 million) using binary search? to search a phone book of the world (6 billion) using binary search?

12 12 Searching example for small N, the difference between O(N) and O(log N) may be negligible consider the following large-scale application: a spell checker  want to read in and store a dictionary of words  then, process a text file one word at a time if word is not found in dictionary, report as misspelled  since the dictionary file is large (117,777 words), the difference will be clear we can define a Dictionary class to store & access words  constructor, contains, size, displayAll, …  note: we can build a dictionary on top of an ArrayList of Strings ArrayList provides all the basic operations we require encapsulating into a Dictionary class allows us to hide later modifications

13 13 Dictionary class import java.util.ArrayList; import java.util.Scanner; import java.io.File; import java.io.FileNotFoundException; public class Dictionary { private ArrayList dict; public Dictionary() { // CONSTRUCTS EMPTY DICTIONARY } public Dictionary(String dictFile) { // CONSTRUCT DICTIONARY WITH WORDS FROM dictFile } public boolean contains(String word) { // RETURNS TRUE IF word IS STORED IN DICTIONARY } public int size() { // RETURNS NUMBER OF WORDS IN DICTIONARY } public void display() { // DISPLAYS ALL WORDS IN DICTIONARY, ONE PER LINE } implement the Dictionary class with the specified methods for now, utilize sequential search (e.g., contains ) download dictionary.txt dictionary.txt from the class directory

14 14 Spell checker import java.util.ArrayList; import java.util.Scanner; import java.io.File; import java.io.FileNotFoundException; import javax.swing.JOptionPane; public class SpellChecker { public static void main(String[] args) { String dictFile = JOptionPane.showInputDialog("Dictionary file:"); Dictionary dict = new Dictionary(dictFile); String textFile = JOptionPane.showInputDialog("Text file:"); try { System.out.println("CHECKING..."); Scanner infile = new Scanner(new File(textFile)); while (infile.hasNext()) { String word = strip(infile.next()); if (word.length() > 0 && !dict.contains(word)) { System.out.println(word); } infile.close(); System.out.println("...DONE"); } catch (FileNotFoundException exception) { System.out.println("NO SUCH FILE FOUND"); } private static String strip(String word) { // CLASS EXERCISE } stores words from a dictionary file processes a user- specified file, displaying each misspelled word note: need to strip non-letters and capitalization from file words before checking

15 15 In-class exercise copy the following files  www.creighton.edu/~davereed/csc222/Code/SpellChecker.java www.creighton.edu/~davereed/csc222/Code/SpellChecker.java  www.creighton.edu/~davereed/csc222/Code/gettysburg.txt www.creighton.edu/~davereed/csc222/Code/gettysburg.txt  www.creighton.edu/~davereed/csc222/Code/poe.txt www.creighton.edu/~davereed/csc222/Code/poe.txt add to the Dictionary project and spell check the Gettysburg address  is the delay noticeable? how about for Poe's The Cask of Amontillado ? now download www.creighton.edu/~davereed/csc222/largeDictionary.txt www.creighton.edu/~davereed/csc222/largeDictionary.txt and spell check the documents with that  largeDictionary.txt is more than twice as big (264,063 words)  does it take more than twice as long?

16 16 Dictionary w/ binary search since the dictionaries are in alphabetical order, we can use binary search  modify the Dictionary class to import the Collections utility class import java.util.Collections;  modify the contains method so that it uses Collections.binarySearch return (Collections.binarySearch(dict, word) >= 0); now spell check the documents using binary search  how much faster is it compared to sequential search  does largeDictionary.txt take more than twice as long?

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